Method for synchronising a gearbox and device for damping the vibrations in gearbox, especially during synchronisation

ABSTRACT

A method for synchronizing a gearbox in a vehicle, whereby the engine and/or the clutch are controlled in a suitable manner during synchronization. In addition, a device for damping the vibrations in a gearbox, especially during synchronization, wherein at least one torsion damper is provided.

The present invention relates to a method for synchronizing a transmission and a device for damping vibrations in a transmission, in particular during synchronization.

Methods of synchronizing a transmission and devices for damping the vibration of a transmission, in particular during synchronization, are known from automotive engineering.

The object of the present invention is to propose a method for synchronizing a transmission in which the synchronization operation is performed as rapidly and as comfortably as possible.

This object is achieved by a method according to the present invention in which the engine and/or the clutch are controlled suitably during synchronization.

This may be accomplished by an engine control in which the engine is controlled without any change in clutch torque, e.g., on the power-shift clutch.

Because of the comfort requirements, the torque on the power-shift clutch may be changed only slowly and in a small range. Therefore, the synchronization operation should be performed essentially through the change in the engine torque. This results in the problem that the engine should be controlled suitably without a change in the torque of the power-shift clutch.

To achieve the object according to the present invention, the gear is synchronized only through engine control. The power-shift clutch transmits a constant torque to the vehicle during the synchronization operation. According to an embodiment of the present invention, the synchronization may be divided at least into two phases. During a first phase, the greatest possible torque difference may be applied. As the set point for the engine control, M_(mot) ^(setpoint)=0 may be preselected for the engine torque for upshifting. The drag torque may act here independently of the engine control. In downshifting, maximum engine torque M_(mot) ^(setpoint)=M_(max) is preferably preselected as the manipulated variable. During a second phase, the engine torque returns to the initial value and the engine set point torque is M_(mot) ^(setpoint)=M₀ where M₀ denotes the initial engine torque.

The point in time t_(u) at which the set point for the engine control is to be switched may preferably depend on the rpm difference to be synchronized and on the load. The time of switching may either be stored in an engine characteristics map and/or determined by the following formula, whereby a distinction is made between upshifting and downshifting: $t_{u} = {\frac{{J_{mot} \cdot \Delta}\quad\omega_{mot}}{M_{0}}\quad({upshifting})}$ $t_{u} = {\frac{{J_{mot} \cdot \Delta}\quad\omega_{mot}}{M_{0} - M_{\max}}\quad({downshifting})}$ where

-   J_(mot)=inertia of the engine; -   Δω_(mot)=rpm difference to be synchronized; -   M₀=initial engine torque; -   M_(max)=maximum engine torque; -   t_(u)=time of switching.

These equations are valid in particular in the case of identical time constants of the engine for the increase in torque (T_(mot) ⁺) and the decrease in torque (T_(mot) ⁻).

With this simplified and robust control strategy according to the present invention, the torque of the power-shift clutch is assumed to be constant during the synchronization operation. The kinetic torque obtained from the engine may then be calculated as the sum of the areas S₁ and S₂ obtained with a graphic plot of the actual engine torque over time.

Up to the point in time of switching t_(u) the engine torque changes according to the following equation: (M _(mot) −M _(drag))=−M _(drag)+(M _(drag) +M ₀)exp(−t/T _(mot)) M ₀ =M _(mot) _(—) ₀ −M _(drag) =M _(LSK) _(—) ₀ where the engine torque at the point in time of switching is: (M _(mot) −M _(drag))=−M _(drag)+(M _(drag) +M ₀)exp(−t _(u) /T _(mot))

The engine torque thus changes according to the following equation: (M _(mot) −M _(drag))=M ₀−(M ₀ −M _(u))exp(−(t−t _(u))/T _(mot))

The areas S₁ and S₂ are calculated as follows: $\begin{matrix} {S_{1} = {{M_{0}t_{u}} - {\int_{0}^{t_{u}}{M_{mot}{\mathbb{d}t}}}}} \\ {= {{\left( {M_{0} + M_{drag}} \right)t_{u}} + {{T_{mot}\left( {M_{drag} + M_{0}} \right)}\left( {{\exp\left( {{- t}/T_{mot}} \right)} - 1} \right)}}} \end{matrix}$ $\begin{matrix} {S_{2} = {\left( {M_{0} - M_{u}} \right){\int_{0}^{\infty}{{\exp\left( {{- t}/T_{mot}} \right)}{\mathbb{d}t}}}}} \\ {= {{- {T_{mot}\left( {M_{drag} + M_{0}} \right)}}\left( {{\exp\left( {{- t_{u}}/T_{mot}} \right)} - 1} \right)}} \end{matrix}$

The total change in kinetic torque thus amounts to: S=S ₁ +S ₂=(M ₀ +M _(drag))t _(u)

The time of switching is calculated from this as follows by using the rpm difference that is to be synchronized: $t_{u} = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0} + M_{drag}} = \frac{J_{mot}\Delta\quad\omega_{mot}}{M_{{mot\_}0}}}$

The advantages of the control strategy proposed here include in particular the fact that it is simple and robust with respect to the dead time of the engine and it presupposes only a PT1-like engine performance. This strategy may be improved by additional “observers” to determine the prevailing drag torque and/or rolling resistance.

Furthermore, the method according to the present invention is advantageous in particular at a moderate rpm. Above an engine rpm of 5000, very good synchronization results are preferably achieved by the method according to the present invention. In the extreme case at approximately 6000 rpm, a time savings of approximately 0.06 s may be implemented due to the optimum control. Since the output torque remains unchanged during synchronization, in this case there are no comfort problems.

When the time constants differ greatly and the rpm difference is relatively small, the point in time of switching is defined by the following equation in the method according to the present invention: τ + exp (−τ) − α  exp (−α  τ) = c ${\tau = {t_{u}/T_{mot}^{-}}},{\alpha = {T_{mot}^{+}/T_{mot}^{-}}},{c = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0}T_{mot}^{-}} + 1 - \alpha}}$

Accordingly the areas S₁ and S₂ are calculated as follows in the case of different time constants for the increase in torque T_(mot) ⁺ and the decrease in torque T_(mot) ⁻: S ₁=(M ₀ +M _(drag))t _(u) +T _(mot) ⁻(M ₀ +M _(drag))(exp(−t _(u) /T _(mot) ⁻)−1) S ₂ =T _(mot) ⁺(M ₀ +M _(drag))(exp(−t _(u) /T _(mot) ⁺)−1) where M₀=M_(set point)−M_(drag).

The following equation holds for the switching time: S₁ + S₂ = J_(mot)Δ  ω_(mot)  and/or $\begin{matrix} {{t_{u}/T_{mot}^{-}} + {\exp\left( {{- t_{u}}/T_{mot}^{-}} \right)} - 1 -} \\ {T_{mot}^{+}/{T_{mot}^{-}\left( {{\exp\left( {{- t_{u}}/T_{mot}^{+}} \right)} - 1} \right)}} \end{matrix} = \frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} + M_{drag}} \right)T_{mot}^{-}}$

With the following equations ${\tau = {t_{u}/T_{mot}^{-}}},{\alpha = {T_{mot}^{+}/T_{mot}^{-}}},{c = {\frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} + M_{drag}} \right)T_{mot}^{-}} + 1 - \alpha}}$ the following equation holds for τ: τ+exp(−τ)−αexp(−ατ)=c

For the parameter it holds that 1≦α≦2 (measured data). At α≠1, the equation may only be solved numerically. At α=1, the solution is τ=c, and the following equation holds: $t_{u} = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0} + M_{drag}} = \frac{J_{mot}\Delta\quad\omega_{mot}}{M_{{mot\_}0}}}$

This corresponds to the simple solution with the same time constants.

The results of the numerical solution and their analysis are given in Table 1 below: TABLE 1 Maximum t_(u) (equation deviation in the (23)) at Maximum deviation exact solution at T_(mot) ⁻ = in the switching time α = 2 0.05 s of t_(u) in the exact c (% of c) (s) solution (s) Comments 2  25% 0.1 0.025 (2-3) T_(interrupt) 3  10% 0.15 0.015 (1-2) T_(interrupt) 5   3% 0.25 0.0075 Deviation not significant 10 0.2% 0.5 0.001 Deviation not significant

This shows that the deviations in downshifting (the case α=0.5 could be critical) are approximately 4 times smaller. The situation in which the values for c are less than 3 is also possible, whereby the rpm difference to be synchronized is minor and the engine torque is large. In this case it is expedient not to perform the synchronization operation with the maximum torque difference but instead to use a moderate torque difference (M₀−M_(sync)).

If the value for c is higher than 4, the switching time t_(u) may be calculated by using the following equation: $t_{u} = \frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} - M_{sync}} \right)}$

In the case when the most accurate possible solution is required, this may be calculated preferably without floating-point operations as a function of c, T_(mot) ⁻, T_(mot) ⁺. An engine characteristics map for the function exp(−c) must be calculated and/or stored.

The advantages of this strategy include in particular its simplicity and robustness with respect to the variables such as the drag torque, the rolling resistance, and the dead time of the controlled system.

In addition, the object of the present invention may be achieved by performing a control intervention on the power-shift clutch as well as on the internal combustion engine of the vehicle in the method for synchronization, in particular of a seamless transmission, in order to implement the fastest possible synchronization operation.

It has been recognized here that at the end of the seamless transmission synchronization operation, the rpm difference in the desired gear as well as the acceleration difference should both assume a value of 0 as accurately as possible. The synchronization operation should be ended as quickly as possible. Because of the comfort requirements, only small torque gradients are allowed on the power-shift clutch. Therefore, the synchronization operation should be implemented essentially through the change in the engine torque. Ultimately the engine torque should nevertheless achieve the original value.

According to the proposed method, a simple control may be employed during the first phase of the synchronization operation and the set point value of the engine torque may be brought to the original value and stabilized on the power-shift clutch during the second phase. For the control phase (first phase) it is indicative that both the engine torque as well as the clutch torque may be switched preferably twice. The first switch may take place, for example, as soon as the synchronization has begun. In upshifting, the set point torque of the engine may preferably be reduced to a value of zero, and the clutch torque may be increased as quickly as possible while taking into account the comfort factor. Conversely, in downshifting, the set point torque of the engine may be raised to the maximum torque, for example, and the clutch torque may be reduced as quickly as possible. The next switching of the set point torques may take place at different points in time. The engine torque may be switched to the maximum value in upshifting or switched to a value of zero in downshifting. The torque on the power-shift clutch may accordingly be reduced in upshifting and/or decreased in downshifting as rapidly as possible.

The switching points may preferably be determined from the engine characteristics map which depends on the initial load and/or the rpm difference to be synchronized and/or they may be stored.

It is also possible for the switching points in time to be calculated by using the following equation systems. Preferably the following computation model is used for this.

An internal combustion engine having a moment of inertia J_(mot) and a vehicle having a moment of inertia J_(Fzg) is taken into account here. The motion equations of the system may be described as follows: J _(mot)ω_(mot) *=M _(mot) −M _(LSK) −M _(drag) J _(Fzg)ω_(Fzg) *=M _(LSK) i _(LSK) −M _(FW) where M_(mot) is the controllable torque of the engine, M_(LSK) is the controllable torque of the power-shift clutch, i_(LSK) is the transmission ratio of the power-shift clutch, M_(drag) is the uncontrollable drag torque and M_(FW) is the rolling resistance of the vehicle converted into torque.

In this analysis, it may be assumed that both the engine and the power-shift clutch are describable as PT1 elements. This may be confirmed by suitable measurements, which also indicate a dead time, in particular in the internal combustion engine.

Accordingly, the engine performance is described as follows in terms of the technical control aspects: T _(mot) M _(mot) *+M _(mot) ={overscore (M)} _(mot) +u _(mot) T _(LSK) M _(LSK) *+M _(LSK) ={overscore (M)} _(LSK) +u _(LSK) T_(mot) and T_(LSK) are the time constants of the internal combustion engine and/or the power-shift clutch. Constants {overscore (M)}_(mot) and {overscore (M)}_(LSK) together with controls u_(mot) and u_(LSK) determine the set point variables of the corresponding torques. Controls u_(mot) and u_(LSK) are limited. However, the reasons for these limits are varied. The internal combustion engine is unable to generate negative torque, the drag torque having already explicitly been taken into account. Therefore, it is advisable to reformulate the limits 0≦M_(mot)≦M_(mot max) as follows: {overscore (M)} _(mot) =M _(mot max)/2 |u _(mot) |≦u _(mot max) =M _(mot max)/2

However, the requirement of the control of the power-shift clutch is determined by comfort and may be formulated as follows: {overscore (M)} _(LSK) =M _(LSK)(t=0) |u _(LSK) |≦u _(LSK max)=max(degree(M _(LSK)))/T _(LSK)

The system must still be completed with initial conditions and final requirements. The initial conditions are formulated at the point in time when the previous gear has been disengaged. At this point in time, the following holds: ω_(mot)(0)=ω₀; ω_(Fzg)(0)=ω₀ /i ₁ ; M _(mot)(0)=M ₀; ω_(Fzg)*(0)=ω_(mot)*(0)/i ₁

The final requirements are formulated as follows: the velocities and the accelerations of both masses should conform to the subsequent gear, and the engine torque should correspond to the initial level: ω_(mot)(T)=i ₂ω_(Fzg)(T); ω_(mot)*(T)=i ₂ω_(Fzg)*(T); M _(mot)(T)=M _(mot)(0)=M ₀

Uniform equations and parameters are now introduced: X₁ = M_(mot); X₂ = M_(LSK); X₃ = J_(mot)ω_(mot); X₄ = J_(Fzg)ω_(Fzg)/i_(LSK) ${M_{W} = {M_{FW}/i_{LSK}}};{{\overset{\_}{M}}_{mot} = U_{1}};{{\overset{\_}{M}}_{LSK} = U_{2}};$ u_(mot_max) = u_(1max ); u_(LSK_max) = u_(2max ); ${k_{1} = {i_{1}i_{LSK}\frac{J_{mot}}{J_{Fzg}}}};{k_{2} = {i_{1}i_{LSK}{\frac{J_{mot}}{J_{Fzg}}.}}}$

The motion equations, the initial conditions, and the final requirements may then be rewritten according to the following equation system: X₁^(•)T₁ + X₁ = U₁ + u₁ X₂^(•)T₂ + X₂ = U₂ + u₂ X₃^(•) = X₁ − X₂ − M_(S) X₄^(•) = X₂ − M_(W) X₁(0) = M₀ ${X_{2}(0)} = {M_{0{\_ LSK}} = \frac{M_{0} - M_{S} + {k_{1}M_{W}}}{1 + k_{1}}}$ X₃(0) = J_(mot)ω_(mot)(0) ${X_{4}(0)} = {\frac{1}{k_{1}}J_{mot}{\omega_{mot}(0)}}$ X₁(T) = M₀ ${X_{2}(T)} = {M_{T\_ LSK} = \frac{M_{0} - M_{S} + {k_{2}M_{W}}}{1 + k_{2}}}$ X₃(T) = k₂X₄(T)

According to Pontriagin's “maximum principle,” the Hamilton function $H = {\sum\limits_{i}{\psi_{i}f_{i}}}$ which is introduced for this equation system above, may be represented in the form X*=f(X, U), where the unknown functions ψ_(i) are determined by the conjugated equation system above: $\psi_{i}^{*} = {- \frac{\partial H}{\partial x_{i}}}$

In the present case the Hamilton function and the conjugated system are in the following form: $\begin{matrix} {H = {{\frac{U_{1} + u_{1} - X_{1}}{T_{1}}\psi_{1}} + {\frac{U_{2} + u_{2} - X_{2}}{T_{2}}\psi_{2}} +}} \\ {{\left( {X_{1} - X_{2} - M_{s}} \right)\psi_{3}} + {\left( {X_{2} - M_{W}} \right)\psi_{4}}} \end{matrix}$ ψ₁^(*) = ψ₁/T₁ − ψ₃; ψ₂^(*) = ψ₂/T₂ + ψ₃ − ψ₄; ψ₃^(*) = 0; ψ₄^(*) = 0

The general solution of the conjugated equation system is to be found with the following equation: ψ₁ =C ₁ e ^(t/T) ¹ +C ₃ T ₁; ψ₂ =C ₂ e ^(t/T) ² +(C ₄ −C ₃)T ₂; ψ₃ =C ₃; ψ₄ =C ₄ C₁ to C₄ are constants that are determined. The Hamilton function may now be described explicitly: $\begin{matrix} {H = {{\frac{U_{1} + u_{1} - X_{1}}{T_{1}}\left( {{C_{1}{\mathbb{e}}^{t/T_{1}}} + {C_{3}T_{1}}} \right)} +}} \\ {{\frac{U_{2} + u_{2} - X_{2}}{T_{2}}\left( {{C_{2}{\mathbb{e}}^{t/T_{2}}} + {\left( {C_{4} - C_{3}} \right)T_{2}}} \right)} +} \\ {{\left( {X_{1} - X_{2} - M_{s}} \right)C_{3}} + {\left( {X_{2} - M_{W}} \right)C_{4}}} \end{matrix}$

The control will thus be the fastest when the Hamilton function is at a maximum with respect to the variables u₁, u₂. Accordingly it holds that: $u_{1} = {u_{1\max}{{sign}\left( {{C_{1}{\mathbb{e}}^{\frac{t}{T_{1}}}} + {C_{3}T_{1}}} \right)}}$ $u_{2} = {u_{2\max}{{sign}\left( {{C_{2}{\mathbb{e}}^{\frac{t}{T_{2}}}} + {\left( {C_{4} - C_{3}} \right)T_{2}}} \right)}}$ Each of the functions in brackets may not change its sign more than once. Therefore, the optimum control may be described as follows: $u_{1} = {u_{10} - {2u_{10}\underset{\_}{1}\left( {t - t_{1}} \right)}}$ $u_{2} = {u_{20} - {2u_{20}\underset{\_}{1}\left( {t - t_{2}} \right)}}$ u₁₀ = ±u_(1max ) u₂₀ = ±u_(2max ) ${\underset{\_}{1}(z)} = \left\{ \begin{matrix} {{0\quad{if}\quad z} < 0} \\ {{1\quad{if}\quad z} > 0} \end{matrix} \right.$

If this control is used in the equation system, the following solution is obtained when the initial conditions are taken into account: $\begin{matrix} {X_{1} = {{M_{0}{\mathbb{e}}^{{- t}/T_{1}}} + {\left( {U_{1} + u_{10}} \right)\left( {1 - {\mathbb{e}}^{{- t}/T_{1}}} \right)} -}} \\ {2{{u_{10}\left( {1 - {\mathbb{e}}^{{- {({t - t_{1}})}}/T_{1}}} \right)} \cdot \underset{\_}{1}}\left( {t - t_{1}} \right)} \end{matrix}$ $\begin{matrix} {X_{2} = {{M_{0{\_ LSK}}{\mathbb{e}}^{{- t}/T_{2}}} + {\left( {U_{2} + u_{20}} \right)\left( {1 - {\mathbb{e}}^{{- t}/T_{2}}} \right)} -}} \\ {2{{u_{20}\left( {1 - {\mathbb{e}}^{{- {({t - t_{2}})}}/T_{2}}} \right)} \cdot \underset{\_}{1}}\left( {t - t_{2}} \right)} \end{matrix}$ $\begin{matrix} {X_{3} = {X_{30} + {M_{0}{T_{i}\left( {1 - {\mathbb{e}}^{{- t}/T_{1}}} \right)}} + {\left( {U_{1} + u_{10}} \right)T_{1}\left( {{t/T_{1}} - 1 + {\mathbb{e}}^{{- t}/T_{1}}} \right)} -}} \\ {{2u_{10}{{T_{1}\left( {\frac{t - t_{1}}{T_{1}} + 1 - {\mathbb{e}}^{\frac{t - t_{1}}{T_{1}}}} \right)} \cdot \underset{\_}{1}}\left( {t - t_{1}} \right)} -} \\ {{M_{0{\_ LSK}}{T_{2}\left( {1 - {\mathbb{e}}^{{- t}/T_{2}}} \right)}} - {\left( {U_{2} + u_{20}} \right){T_{2}\left( {{t/T_{2}} - 1 + {\mathbb{e}}^{{- t}/T_{2}}} \right)}} +} \\ {{2u_{20}{{T_{2}\left( {\frac{t - t_{2}}{T_{2}} + 1 - {\mathbb{e}}^{\frac{t - t_{2}}{T_{2}}}} \right)} \cdot \underset{\_}{1}}\left( {t - t_{2}} \right)} - {M_{S}t}} \end{matrix}$ $\begin{matrix} {X_{4} = {X_{40} + {M_{0{\_ LSK}}{T_{2}\left( {1 - {\mathbb{e}}^{{- t}/T_{2}}} \right)}} +}} \\ {{\left( {U_{2} + u_{20}} \right){T_{2}\left( {{t/T_{2}} - 1 + {\mathbb{e}}^{{- t}/T_{2}}} \right)}} -} \\ {{2u_{20}{{T_{2}\left( {\frac{t - t_{2}}{T_{2}} + 1 - {\mathbb{e}}^{\frac{t - t_{2}}{T_{2}}}} \right)} \cdot \underset{\_}{1}}\left( {t - t_{2}} \right)} - {M_{W}t}} \end{matrix}$

This solution depends upon three unknown constants: switching times t₁ and t₂ and total time T. These are determined by three final requirements. If total time T is predetermined, the equations for t₁ and t₂ may be solved explicitly. Accordingly, the entire system is reduced to a single transcendent equation, the solutions to which may be stored in the form of an engine characteristics map. The efficacy of optimum control has been verified by simulations with MATLAB and ITI-SIM.

The calculated times for synchronization may be plotted as a function of rpm and load. Two trends are discernible. The time required for synchronization increases with the rpm difference to be overcome and decreases with an increase in load. These relationships may be explained with a very simple model.

The comfort-related restriction on the gradient of the torque on the power-shift clutch does not allow any noticeable change in torque during the synchronization phase. Therefore, the torque of the power-shift clutch may be assumed to be constant in first approximation. The torque is determined by the gear-disengagement phase. The deflection coupling of the “first” gear must be disengaged here. This means that the torque of the power-shift clutch corresponds in first approximation to the engine torque. If it is assumed at first that the control is infinitely fast, the torque of the engine may be reduced immediately and increased again suddenly only after synchronization. This yields the following motion equation for the engine to be synchronized: J _(motω) *=−|M _(drag) |−M _(LSK)

If it is also assumed that the vehicle rpm does not change during the shifting operation, a simple equation for the synchronization time may be obtained: ${\Delta\quad t} = {\frac{\pi\quad n}{30} \cdot \left( {1 - \frac{i_{2}}{i_{1}}} \right) \cdot \frac{J_{mot}}{\left| M_{drag} \middle| {+ M_{{mot\_}0}} \right.}}$

If the time constants of the engine control are taken into account, it is discernible that the engine torque is switched twice. A final estimate of the synchronization time may be obtained in this way: ${\Delta\quad t} = {{\frac{\pi\quad n}{30} \cdot \left( {1 - \frac{i_{2}}{i_{1}}} \right) \cdot \frac{J_{mot}}{\left| M_{drag} \middle| {+ M_{{mot\_}0}} \right.}} + {2T_{mot}}}$

This shows that the estimate corresponds very well to the times actually achievable and that low loads correlate with very long times.

As soon as the set point/actual rpm difference has fallen below a threshold, it is possible for a second phase of the method to begin according to a further embodiment of the present invention. The engine torque may preferably asymptotically approach the original level and the power-shift clutch must no longer be controlled in an advantageous manner but instead it is brought to the point of smoothing out the remaining rpm difference by a simple regulation (e.g., PI or PID regulator). The threshold which is also responsible for the transition to the second phase may also be determined from the engine characteristics map which depends on the initial load and the rpm difference to be synchronized and/or it may be stored.

This is explained below on the basis of regulation strategies. The switching points that are decisive for the control strategy described here respond to possible interference and initial conditions. Therefore, a simple regulation that functions fully automatically is proposed. A simple PI regulator is used for control of the power-shift clutch and the switching point of the engine control may preferably be determined by a PID regulator with limits. As soon as the value has fallen below a certain threshold of the rpm difference, the engine regulator may be switched off. The set point torque of the engine is equated with the desired end torque. The end regulation may be performed by the power-shift clutch regulator.

It may be assumed that there is no noticeable dead time in the control. In reality, however, there is a certain dead time. If this is known, it does not change anything for the optimum control. However, there may be changes for the regulation described here. In this case, a similar regulation may be used. The only difference is that the switch to the final regulation by the power-shift clutch regulator takes place when a threshold that depends on load and rpm is exceeded, this threshold being stored in the form of an engine characteristics map. The dead time may amount to approximately 0.1 s.

With the method proposed here, in particular with respect to speed, an optimum control for synchronization is implemented. The method according to the present invention may be used with any transmission systems.

In addition, the object of the present invention is to propose a device for damping vibrations in a transmission so as to permit an effective synchronization operation for the transmission.

This object is achieved in particular by the fact that at least one suitable torsion damper is provided.

The configuration and implementation of a torsion damper may thus be provided in a drive train of a motor vehicle, preferably having a seamless transmission, an electric transmission, or the like.

According to a further advantageous embodiment, the torsion damper used may be based on the principles of the dual-mass flywheel (DMF) and may be referred to as a DMF damper.

For an effective synchronization operation in a seamless transmission, very good vibration isolation is crucial in particular in the form-fitting part of the transmission. Adequate vibration isolation may not be guaranteed with conventional embodiments.

The embodiment according to the present invention involves the use of a DMF-like damper which is preferably effectively integrated into the seamless transmission-specific structure of the drive train.

It is also possible for the vibrations to be reduced through the regulating technology. However, the vibrations that occur have a very high frequency so that design or strategic measures are preferably used. As a measure involving the regulating technology, it is possible to provide for shifting to be performed with a slipping low-gear clutch.

Another possibility is to use the torsion damper, which also uses the additional mass of the power-shift clutch to combat engine-excited vibration like the secondary part of a DMF.

In a further embodiment of the present invention, the torsion damper, i.e., DMF damper, may be situated in the drive train. For example, the DMF damper may be situated upstream from both clutches, e.g., a low-gear clutch and a power-shift clutch.

It is also possible that the damper is situated between the two clutches mentioned above. The advantage of this embodiment is that the masses of the two clutches already present are also used for the damper. The damper may perhaps also be implemented downstream from the clutches, virtually in the transmission. This configuration is particularly appropriate when the mass of an electric machine implemented in the transmission may be used as a secondary part of the damper.

With all possible configurations, adequate isolation of vibration may be ensured through a suitable choice of the masses and rigidities.

Use of an arc spring damper as the torsion damper is particularly advantageous. The device according to the present invention may preferably be used in a seamless transmission, an electric transmission, or the like.

The patent claims filed with the application are formulation proposals without prejudice of the achievement of broader patent protection. The applicant reserves the right to claim additional feature combinations previously only disclosed in the description and/or the drawing.

The references used in the dependent claims indicate further refinements of the subject matter of the main claim by the features of the particular dependent claim. They are not to be understood as a waiver of obtaining an independent claim for the combination of features of the referenced dependent claims.

Because the subject matter of the dependent claims may form separate independent inventions with respect to the related art on the priority date, the applicant reserves the right to make them the subject matter of independent claims or division clarifications. They may furthermore also contain independent inventions having a design that is independent of the subject matter of the aforementioned dependent claims.

The exemplary embodiments are not to be understood as limitations of the present invention. Rather, numerous modifications and variants are possible within the present disclosure, in particular variants, elements, and combinations and/or materials that are obvious to those skilled in the art regarding the achievement of the object of the present invention, for example, by combination or modification of individual features or elements or method steps described in the general description and embodiments as well as in the claims and contained in the drawing, resulting in a new object or new method steps or method step sequences via combinable features, including those concerning manufacturing, testing, and work methods.

Other advantageous embodiments are derived from the subclaims and the accompanying drawing, in which:

FIG. 1 shows a possible model for simulation of synchronization in a vehicle;

FIG. 2 shows a diagram of the actual engine torque during synchronization over time;

FIG. 3 a shows curves for the set point rpm and the rotational speed of the engine over time with optimum engine control according to the present invention;

FIG. 3 b shows curves for the torques of the engine and clutch over time with optimum engine control according to the present invention;

FIG. 4 shows various curves of the time for synchronization over the rpm with optimum control;

FIG. 5 a shows curves for the set point rpm and the rotational speed of the engine over time;

FIG. 5 b shows curves for engine torque, clutch torque, and output torque over time;

FIG. 6 shows various curves of the time for synchronization over the rpm with a limit to the change in clutch torque on the power-shift clutch of 30 Nm/s with optimum power-shift clutch control and engine control;

FIG. 7 shows various curves of the time for synchronization over the rpm according to an estimate;

FIG. 8 a shows curves for the set point rpm and the rotational speed of the engine over time;

FIG. 8 b shows curves for the engine torque, the clutch torque, and the output torque over time;

FIG. 9 shows various curves of the time for synchronization over the rpm with a limit to the change in the clutch torque on the power-shift clutch of 30 Nm/s by a power-shift clutch control and engine control;

FIG. 10 shows various curves of the time for synchronization over the rpm with a limit to the change in the clutch torque on the power-shift clutch of 30 Nm/s by a power-shift clutch control and engine control with a dead time of the engine of 0.1 s;

FIG. 11 a shows curves for the set point rpm and the rotational speed of the engine over time with simple regulation with a dead time;

FIG. 11 b shows curves for the engine torque, the clutch torque, and the output torque over time with simple regulation with a dead time;

FIG. 12 shows curves for the set point rpm, the rotational speed of the transmission input shaft, and the rotational speed of the engine over time when using a conventional damper;

FIG. 13 shows curves for the set point rpm, the rotational speed of the transmission input shaft, and the rotational speed of the engine over time when using an arc spring damper according to the present invention;

FIG. 14 shows a partial view of a drive train having torsion-damped clutch disks;

FIG. 15 shows a partial view of a drive train having a torsion damper according to the present invention between the crankshaft and the low-gear clutch;

FIG. 16 shows a partial view of a drive train having a torsion damper according to the present invention between the power-shift clutch and the low-gear clutch and

FIG. 17 shows a partial view of a drive train having a torsion damper according to the present invention downstream from the power-shift clutch.

FIG. 1 shows a model including an engine 101 and a power-shift clutch 102 in a transmission of a motor vehicle 103 in a schematic representation. This model is used as the basis for simulation of synchronization.

According to a simplified and robust control strategy according to the present invention the torque of power-shift clutch 102 is assumed to be constant during the synchronization operation. The kinetic torque which is subtracted from the engine torque of engine 1 may be calculated from the sum of areas S₁ and S₂ which are depicted in FIG. 2, which shows the actual engine torque during synchronization over time.

According to this, the engine torque changes according to the following equation: (M _(mot) −M _(drag))=−M ₀−(M ₀ +M _(u))exp(−(t−t _(u))/T _(mot))

The areas S₁ and S₂ are calculated as follows: $\begin{matrix} {S_{1} = {{{M_{0}t_{u}} - {\int_{0}^{t_{u}}{M_{mot}{\mathbb{d}t}}}} = {{\left( {M_{0} + M_{drag}} \right)t_{u}} +}}} \\ {{T_{mot}\left( {M_{drag} + M_{0}} \right)}\left( {{\exp\left( {{- t_{u}}/T_{mot}} \right)} - 1} \right)} \end{matrix}$ $\begin{matrix} {S_{2} = {{\left( {M_{0} - M_{u}} \right){\int_{0}^{\infty}{{\exp\left( {{- t}/T_{mot}} \right)}{\mathbb{d}t}}}} = -}} \\ {{T_{mot}\left( {M_{drag} + M_{0}} \right)}\left( {{\exp\left( {{- t_{u}}/T_{mot}} \right)} - 1} \right)} \end{matrix}$

The total change in kinetic torque is as follows: S=S ₁ +S ₂=(M ₀ +M _(drag))t _(u)

FIG. 3 a shows the curves for the set point rpm a) and the rotational speed b) of the engine over time. These curves are obtained with optimum engine control according to the present invention.

FIG. 3 b shows the curves for the engine torque a) and the clutch torque b) as well as the output torque c) over time; these are the curves obtained with optimum engine control according to the present invention.

FIG. 4 shows various curves of the time for synchronization over the rpm with optimum control, the top curve showing the time for synchronization at a torque of 75 Nm, the middle curve showing the time for synchronization at a torque of 100 Nm and the bottom curve showing the time for synchronization at a torque of 125 Nm.

As FIG. 4 shows, the strategy at a moderate rpm is barely inferior to optimum control. Only above 5000 rpm are the advantages of optimum control clearly manifest. In the extreme case (6000 rpm) optimum control is 0.06 s faster. Since the output torque does not change during synchronization, no comfort problems need be expected in this case.

FIG. 4 shows the calculated times for synchronization over the rpm and load for a 1-2 shift. Two clear trends are discernible. The time required for synchronization increases with the rpm difference to be overcome (and accordingly with the rpm of engine 1) and decreases with an increase in load.

FIGS. 5 a and 5 b show a typical synchronization operation. In FIG. 5 a, the curves for set point rpm a) and rotational speed b) of the engine are plotted over time.

FIG. 5 b shows the curves for engine torque a), clutch torque b), and output torque c) over time as obtained with a synchronization strategy according to the present invention.

FIG. 6 shows various curves of the time for synchronization over the rpm, the upper curve showing the time for synchronization at a torque of 75 Nm, the middle curve showing the time for synchronization at a torque of 100 Nm, and the bottom curve showing the time for synchronization at a torque of 125 Nm. The change in the clutch torque on the power-shift clutch is limited to 30 Nm/s, an optimum power-shift clutch control and engine control according to the method of the present invention being used.

FIG. 7 shows various curves of the time for synchronization over the rpm according to an estimate, showing the time for synchronization at a torque of 0 Nm, 25 Nm, 50 Nm, 75 Nm, 100 Nm, and 125 Nm for the upper curve to the bottom curve, respectively.

The resulting times are calculated on the basis of the values for J_(mot)=0.176 kgm², M_(drag)=25 Nm, i₁=3.27, and i₂=1.92. It may be seen here that the estimate corresponds very well to the times actually achievable and that at low loads the time may be very long.

FIGS. 8 a and 8 b show a typical synchronization operation, FIG. 8 a showing curves for set point rpm a) and rotational speed b) of the engine over time.

FIG. 8 b shows curves for engine torque a), clutch torque b), and output torque c) over time.

FIG. 9 shows the various curves of the time for synchronization over rpm, the upper curve showing the time for synchronization at a torque of 75 Nm, the middle curve showing the time for synchronization at a torque of 100 Nm, and the lower curve showing the time for synchronization at a torque of 125 Nm.

The change in clutch torque on the power-shift clutch is limited to 30 Nm/s here. The calculated and plotted times are obtained by a power-shift clutch control and engine control according to the present invention for synchronization of rpm and applied load.

It is assumed here that no noticeable dead time occurs in the control. In reality, however, there is a certain dead time. If this is known, it does not change anything in terms of the optimum control but it does change the regulation described here. In this case, a similar regulation has been developed. The only difference is that the switch to the final regulation by the power-shift clutch regulator takes place on exceeding a threshold which depends on rpm and load and has been stored as an engine characteristics map. Dead time in the simulation is 0.1 s. The corresponding simulation results are shown in FIGS. 10, 11 a, and 11 b. This shows that the method according to the present invention achieves optimum control of the synchronization operation with respect to speed.

The top curve in FIG. 10 shows the time for synchronization at a torque of 75 Nm, the middle curve shows the time for synchronization at a torque of 100 Nm, and the lower curve shows the time for synchronization at a torque of 125 Nm.

FIG. 11 a shows curve a) for the set point rpm and curve b) for the rotational speed of the engine.

FIG. 11 b shows the curve for the engine torque as a), the curve for the clutch torque as b), and the curve for the output torque as c).

FIG. 12 shows the influence of rpm irregularity when using a conventional damper, with the curves for set point rpm (I), rotation speed (II) of the transmission input shaft, and rotational speed (III) of the engine over time.

However, FIG. 13 shows the influence of rpm irregularity when using a DMF-like damper or an arc spring damper according to the present invention. It may be seen here that as with a normal DMF the irregularity of the engine (curve III) increases. The movement of the transmission input (curve II) that is to be synchronized is definitely calmed, however. This permits form-fitting shifting.

Possible configurations of a “DMF damper” are shown in FIGS. 14 through 17.

FIG. 14 shows torsion-damped clutch disks of power-shift clutch 102 and low-gear clutch 106.

FIGS. 15 through 17 show different configurations of DMF damper 104 in the drive train of the transmission. FIG. 15 shows the DMF damper upstream from the two clutches, namely between crankshaft 105 of engine 101 and low-gear clutch 106. However, in FIG. 16 damper 104 is provided between the aforementioned clutches. The advantage of this design is that the masses of the two clutches already being used for the DMF damper are also used here.

FIG. 17 shows the configuration of DMF damper 104 downstream from clutches 102 and 106. DMF damper 104 is implemented in the transmission in this way. This configuration is appropriate in particular if the mass of an electric engine implemented in the transmission may also be used as a secondary part of the damper.

In all cases, adequate isolation of vibration may be ensured through an appropriate choice of the masses and rigidities. 

1-50: (canceled) 51: A method for operating a transmission of a vehicle having an engine and a clutch, the method comprising: synchronizing the transmission; and suitably controlling at least one of the engine and the clutch during the synchronizing. 52: The method as recited in claim 51, wherein in the transmission is a seamless transmission and the clutch is a power-shift clutch, and wherein the controlling includes controlling the engine so as to transfer a constant torque from the power-shift clutch to the vehicle. 53: The method as recited in claim 52, wherein the controlling includes switching a set point of an engine torque in a quick manner. 54: The method as recited in claim 51, wherein the synchronizing includes synchronizing a gear to be shifted using an engine control. 55: The method as recited in claim 53, wherein the synchronizing includes a first phase, in the set point is set so as to have a large difference from an initial engine torque, and a second phase, in which the set point returns to the initial engine torque. 56: The method as recited in claim 54, further comprising setting the set point to zero using the engine control during an upshifting of the transmission wherein a drag torque acts independently of the engine control. 57: The method as recited in claim 54, further comprising setting the set point to be equal to a maximum engine torque in the engine control during a downshifting of the transmission. 58: The method as recited in claim 54, wherein the set point is switched by the engine control at a point in time, the point in time of the switching being a function of at least one of an rpm difference to be synchronized and an applied load. 59: The method as recited in claim 58, wherein the point in time is determined from an engine characteristics map. 60: The method as recited in claim 58, wherein the point in time of the switching for an upshifting of the transmission is determined using the formula: $t_{u} = \frac{{J_{mot} \cdot \Delta}\quad\omega_{mot}}{M_{0}}$ wherein t_(u)=point in time of the switching, J_(mot)=inertia of the engine, Δω_(mot)=rpm difference to be synchronized, and M₀=initial torque of the engine. 61: The method as recited in claim 58, wherein the point in time of the switching for a downshifting of the transmission is determined using the formula: $t_{u} = \frac{{J_{mot} \cdot \Delta}\quad\omega_{mot}}{M_{0} - M_{\max}}$ wherein t_(u)=point in time of the switching, J_(mot)=inertia of the engine, Δω_(mot)=rpm difference to be synchronized, and M₀=initial torque of the engine. 62: The method as recited in claim 60, wherein the formula is used when a time constant of the engine for an increase in torque and a time constant of the engine for a decrease in torque are identical. 63: The method as recited in claim 61, wherein the formula is used when a time constant of the engine for an increase in torque and a time constant of the engine for a decrease in torque are identical. 64: The method as recited in claim 58, wherein, up to the point in time of the switching, the engine torque changes according to the following equation: (M _(mot) −M _(drag))=−M _(drag)+(M _(drag) +M ₀)exp(−t/T _(mot)) M ₀ =M _(mot) _(—) ₀ −M _(drag) =M _(LSK) _(—) ₀ wherein M_(mot)=engine torque, M_(drag)=drag torque, M₀=initial engine torque, and T_(mot)=time constant of the engine torque. 65: The method as recited in claim 58, wherein, at the point in time of the switching, the engine torque is determined by the following equation: (M _(mot) −M _(drag))=−M _(drag)+(M _(drag) +M ₀)exp(−t _(u) /T _(mot)) wherein M_(mot)=engine torque, M_(drag)=drag torque, M₀=initial engine torque, t_(u)=point in time of the switching, and T_(mot)=time constant of the engine torque. 66: The method as recited in claim 58, wherein after the point in time of the switching, the engine torque changes according to the equation: (M _(mot) −M _(drag))=M ₀−(M ₀ −M _(u))exp(−(t−t _(u))/T _(mot)) wherein M_(mot)=engine torque, M_(drag)=drag torque, M₀=initial engine torque, M_(u)=engine torque at the point in time of the switching, t_(u)=point in time of the switching, and T_(mot)=time constant of the engine torque. 67: The method as recited in claim 58, wherein a change in kinetic torque is derived using the equation: S=S ₁ +S ₂=(M ₀ +M _(drag))t _(u) where it holds that $\begin{matrix} {S_{1} = {{M_{0}t_{u}} - {\int_{0}^{t_{u}}{M_{mot}{\mathbb{d}t}}}}} \\ {= {{\left( {M_{0} + M_{drag}} \right)t_{u}} + {{T_{mot}\left( {M_{drag} + M_{0}} \right)}\left( {{\exp\left( {{- t_{u}}/T_{mot}} \right)} - 1} \right)}}} \end{matrix}$ $\begin{matrix} {S_{2} = {\left( {M_{0} - M_{u}} \right){\int_{0}^{\infty}{{\exp\left( {{- t}/T_{mot}} \right)}{\mathbb{d}t}}}}} \\ {= {{- {T_{mot}\left( {M_{drag} + M_{0}} \right)}}\left( {{\exp\left( {{- t_{u}}/T_{mot}} \right)} - 1} \right)}} \end{matrix}$ wherein S=change in kinetic torque S₁=change in kinetic torque prior to t_(u) S₂=change in kinetic torque after t_(u) M₀=initial engine torque, M_(drag)=drag torque M_(u)=engine torque at the point in time of the switching, t_(u)=point in time of the switching, and T_(mot)=time constant of the engine torque. 68: The method as recited in claim 67, wherein the point in time of the switching is determined by an rpm difference to be synchronized according to the equation: $t_{u} = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0} + M_{drag}} = \frac{J_{mot}\Delta\quad\omega_{mot}}{M_{{mot\_}0}}}$ wherein J_(mot)=inertia of the engine, and Δω_(mot)=rpm difference to be synchronized. 69: The method as recited in claim 58, wherein, when a time constant of the engine for an increase in torque and a time constant of the engine for a decrease in torque are different and a rpm difference is small, the point in time of switching is defined by the following equations: τ + exp (−τ) − α  exp (−α  τ) = c ${\tau = {t_{u}/T_{mot}^{-}}},{\alpha = {T_{mot}^{+}/T_{mot}^{-}}},{c = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0}T_{mot}^{-}} + 1 - \alpha}}$ wherein t_(u)=point in time of the switching, and T_(mot) ⁻=time constant of the engine for a decrease in torque T_(mot) ⁺=time constant of the engine for an increase in torque J_(mot)=inertia of the engine, and Δω_(mot)=rpm difference to be synchronized. 70: The method as recited in claim 69, wherein, when a time constant of the engine for an increase in torque and a time constant of the engine for a decrease in torque are different, the areas S₁ and S₂ are calculated as follows: S ₁=(M ₀ +M _(drag))t _(u) +T _(mot) ⁻(M ₀ +M _(drag))(exp(−t _(u) /T _(mot) ⁻)−1) S ₂ =T _(mot) ⁺(M ₀ +M _(drag))(exp(−t _(u) /T _(mot) ⁺)−1) wherein M₀=M_(set point)−M_(drag) M₀=torque on the engine shaft M_(set point)=engine set point torque M_(drag)=engine drag torque. 71: The method as recited in claim 69, wherein for the point in time (t_(u)) of switching, the following equations hold: S₁ + S₂ = J_(mot)Δ  ω_(mot)  and/or $\begin{matrix} {{t_{u}/T_{mot}^{-}} + {\exp\left( {{- t_{u}}/T_{mot}^{-}} \right)} - 1 -} \\ {T_{mot}^{+}/{T_{mot}^{-}\left( {{\exp\left( {{- t_{u}}/T_{mot}^{+}} \right)} - 1} \right)}} \end{matrix} = \frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} + M_{drag}} \right)T_{mot}^{-}}$ wherein ${\tau = {t_{u}/T_{mot}^{-}}},{\alpha = {T_{mot}^{+}/T_{mot}^{-}}},{c = {\frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} + M_{drag}} \right)T_{mot}^{-}} + 1 - \alpha}}$ and for parameter τ it holds that: τ+exp(−τ)−αexp(−ατ)=c and for parameter α it holds that 1≦α≦2. 72: The method as recited in claim 71, wherein at values of α=1 and τ=c, the point in time (t_(u)) is calculated using the following equation: $t_{u} = {\frac{J_{mot}\Delta\quad\omega_{mot}}{M_{0} + M_{drag}} = \frac{J_{mot}\Delta\quad\omega_{mot}}{M_{{mot\_}0}}}$ 73: The method as recited in claim 72, wherein at values of c>4 the point in time (t_(u)) of the switching is calculated using the following equation: $t_{u} = \frac{J_{mot}\Delta\quad\omega_{mot}}{\left( {M_{0} - M_{sync}} \right)}$ 74: The method as recited in claim 73, further comprising calculating and storing an engine characteristics map for the function exp(−c). 75: The method as recited in claim 51 wherein the transmission is a seamless transmission and the clutch is a power-shift clutch, and wherein the controlling includes controlling the power-shift clutch and the engine. 76: The method as recited in claim 75, wherein the synchronizing includes a implementing a simple control during a first phase of the synchronizing, and during a second phase of the synchronizing, setting a set point of the engine torque to an initial value and adjusting the set point at the power-shift clutch. 77: The method as recited in claim 76, further comprising switching the set point of the engine torque at least twice during the first phase. 78: The method as recited in claim 77, wherein a first switching is performed at the beginning of the synchronizing. 79: The method as recited in claim 78, wherein during an upshifting of the transmission, the set point is switched to zero and a clutch torque is increased quickly. 80: The method as recited in claim 78, wherein during a downshifting of the transmission, the set point value is switched to a maximum engine torque and a clutch torque is reduced quickly. 81: The method as recited in claim 77, further comprising performing additional switching of the set point of the engine torque at different times, the engine torque being switched to a maximum value during upshifting and to a value of zero during downshifting and reducing a clutch torque on the power-shift clutch during upshifting and rapidly increasing the clutch torque during downshifting. 82: The method as recited in claim 77, wherein a point in time of the switching is determined from at least one of a value stored in memory and a characteristics map, wherein the characteristics map depends on at least one of an initial load and an rpm difference to be synchronized. 83: The method as recited in claim 77, wherein a point in time of the switching is determined using a computation model. 84: The method as recited in claim 83, the computation model uses the following motion equations: J _(mot)ω_(mot) *=M _(mot) −M _(LSK) −M _(drag) J _(Fzg)ω_(Fzg) *=M _(LSK) i _(LSK) −M _(FW) wherein M_(mot)=controllable engine torque; M_(LSK)=controllable clutch torque of the power-shift clutch; i_(LSK)=transmission ratio of the power-shift clutch; M_(drag)=uncontrollable drag torque; M_(FW)=rolling resistance converted into torque; J_(Fzg)=moment of inertia of the vehicle; J_(mot)=moment of inertia of the engine. 85: The method as recited in claim 83, wherein the engine and the power-shift clutch are each described as being a PT1 element in the computation model. 86: The method as recited in claims 83, wherein equations of the computation model depend on at least one of a first and a second switching time and a total time such that, at a predetermined total time, the equations of the computation model are solved explicitly for the first and second switching times. 87: The method as recited in one of claim 82, wherein an applied rpm difference and the initial load have an influence on the point of time of switching, the influence being taken into account through the following equation: J _(motω) *=−|M _(drag) |−M _(LSK) 88: The method as recited in claim 87, wherein under an assumption that an rpm of the vehicle does not change during a shifting operation, the following equation is obtained: ${\Delta\quad t} = {\frac{\pi\quad n}{30} \cdot \left( {1 - \frac{i_{2}}{i_{1}}} \right) \cdot \frac{J_{mot}}{{M_{drag}} + M_{{mot\_}0}}}$ 89: The method as recited in claim 88, wherein a time for synchronization is determined using the following equation, taking into account a time constant of the engine control: ${\Delta\quad t} = {{\frac{\pi\quad n}{30} \cdot \left( {1 - \frac{i_{2}}{i_{1}}} \right) \cdot \frac{J_{mot}}{{M_{drag}} + M_{{mot\_}0}}} + {2T_{mot}}}$ 90: The method as recited in claim 89, wherein a second phase of synchronization is begun as soon as a set point/actual rpm difference has dropped below a threshold. 91: The method as recited in claim 90, wherein the engine torque is asymptotically altered to the initial value in the second phase and the power-shift clutch is influenced by a simple regulation so that a remaining rpm difference is smoothed out. 92: The method as recited in claim 91, wherein one of a PI regulator or a PID regulator is used for the regulation. 93: The method as recited in claim 90, wherein the threshold is determined from the engine characteristics map which depends on the initial load and the rpm difference to be synchronized and wherein the threshold is stored. 94: A device for damping vibrations in a transmission, comprising: at least one torsion damper. 95: The device as recited in claim 94, wherein the transmission is one of a seamless transmission and an electric transmission. 96: The device as recited in claim 94, wherein the torsion damper includes an arc-spring damper functioning according to the principle of a dual-mass flywheel. 97: The device as recited in claim 96, further comprising a power-shift clutch, and wherein an additional mass of the power-shift clutch is used as a secondary mass of the damper so as to reduce engine-excited vibrations. 98: The device as recited in claim 94, further comprising a plurality of clutch disks, the torsion damper being disposed in an area of the clutch disks. 99: The device as recited in claim 94, wherein the torsion damper is disposed upstream from a low-gear clutch and a power-shift clutch. 100: The device as recited in one claim 94, wherein the torsion damper is disposed between a low-gear clutch and a power-shift clutch. 101: The device as recited in claim 94, wherein the torsion damper is disposed downstream from a low-gear clutch and a power-shift clutch. 102: The device as recited in claim 94, wherein the torsion damper is configured to dampen vibrations in the transmission during a synchronization. 